A nanotechnology lab produces a new material that doubles in volume every 2 hours. If they start with 5 cubic centimeters, what will be the volume after 12 hours? - NBX Soluciones

Understanding the Context

A Breakthrough in Nanotechnology: The Self-Doubling Material

In a stunning advancement in nanotechnology, a pioneering research lab has engineered a unique material with extraordinary growth properties: it doubles in volume every 2 hours. This rapid self-replication presents transformative possibilities across industries—from medicine and environmental cleanup to advanced manufacturing.

Start with just 5 cubic centimeters (cm³) of this material at time zero. Where does it lead after 12 hours? The answer is astonishing: 5,120 cm³. But how?

The Science Behind the Growth

Key Insights

The doubling behavior follows a pattern of exponential growth over 12-hour intervals. Because the material doubles every 2 hours, we divide the total time into halves:

12 hours ÷ 2 hours = 6 doubling periods

Starting volume: 5 cm³
After each period, the volume multiplies by 2:

• After 2 hours: 5 × 2 = 10 cm³
  
• After 4 hours: 10 × 2 = 20 cm³
  
• After 6 hours: 20 × 2 = 40 cm³
  
• After 8 hours: 40 × 2 = 80 cm³
  
• After 10 hours: 80 × 2 = 160 cm³
  
• After 12 hours: 160 × 2 = 5,120 cm³

Alternatively, using exponential growth formula:

Final Thoughts

Final Volume = Initial Volume × (2)^(time / doubling time)
Final Volume = 5 × 2⁶ = 5 × 64 = 320 × 16 = 5,120 cm³

What Does This Mean?

This material’s explosive expansion under controlled conditions challenges conventional limits in material engineering. Imagine revolutionizing drug delivery systems with bio-scalable structures, producing lightweight but expandable nanoscale components, or even creating self-replicating nanomaterials for construction at microscopic scales.

Of course, doubling every two hours in a lab environment requires precise nanoscale control—researchers must carefully manage temperature, surface area, and energy input to maintain safe, predictable growth.

Future Applications and Implications

While long-term stability and containment remain critical research areas, this breakthrough paves the way for:

• Smart Nanomaterials that grow to fulfill specific functions
  
• In-situ Manufacturing using minimal starting material
  
• Breakthroughs in micromedicine, including smart implants or self-adjusting therapeutic carriers